Digital ink-jet glass printer

ABSTRACT

Digital ink-jet glass printer for printing flat glass boards with glass based ink is disclosed, comprising; (a) horizontal support for a glass board to be printed; (b) at least one digital ink-jet printing head moveable from above the area of a glass board supported by the horizontal support by means of a respective moving mechanism, the printing head is capable of moving above the glass board and injecting glass based ink according to positioning and injecting commands received from a computer or controller; (c) ink supply system in liquid communication with the at least one printing head. Method for printing flat glass boards with glass based ink, is also disclosed, comprising; (a) providing a computer memory with image to be printed; (b) positioning a glass plate to be printed underneath at least one digital ink-jet printing head capable of receiving from the computer and accordingly executing ink jetting commands and positioning commands; (c) providing the at least one printing head with jetting and positioning commands corresponding to the image to be printed; (d) supplying to the printing head glass based ink in a substantially unified heterogenic suspension in quantities sufficient for printing the image; (e) drying or curing the image until a primary fixation is achieved sufficient for safely conveying the printed glass plate to completing the ink fixation in a furnace.

This is a National Phase Application filed under 35 U.S.C. 371 as anational stage of PCT/IL2004/000776, filed Aug. 25, 2004, an applicationclaiming the benefit under 35 U.S.C. 119(e) U.S. Provisional ApplicationNo. 60/497,311, filed Aug. 25, 2003, the entire content of each of whichis hereby incorporated by reference in its entirety.

FIELD OF THE INVENTION

The present invention relates to the field of glass printing, andespecially to printing on flat safety glass.

BACKGROUND OF THE INVENTION

Printing on flat glass boards for decoration or coloring purposesinvolves unique techniques for feeding printing and affixing the printedimage on the glass board for long term lasting on the finished product.The techniques currently known in the art for glass printing are muchmore complicated, and as a result—also expensive, comparing to printingmethods for printing on surfaces of other materials thus often do notfit for printed glass boards in mass production and in acceptable costs.Accordingly, the market of decoratively printed glasses is not a verydeveloped one, and thus in general a plain (i.e. not printed) glass iscommonly used for doors, windows or other glass barriers. This isdespite of the fact that painted glass could be a source of pleasingdecoration and may involve unique effects when combined with eithernatural or artificial illumination designs, as could be appreciated fromsites where such decoration is already in use.

The problems involved in glass printing mainly result from its surfacesmoothness, its material stiffness and its wet repulsion characteristicswhich do not allow for impressing it with conventional inks havingconventional drying attributes. Accordingly, special ink compositionsare used for long lasting glass printing, which are commonly includenano particles of glass, wherein the fixation of the printed image is byfiring the printed glass in a furnace at high temperatures of 550° C.and more. The exposure of the ink to such high temperature causes theglass micro (or nano) particles to melt, thus affixing the ink pigmentsinto the printed glass surface.

As a result, currently methods for glass printing are mainly based onscreen-printing (or silk-printing, both will be referred to hereinafteras “screen-printing”) that is the only known method for handling theunique ink compositions that should be used for long lasting printing onflat glass boards.

There are several disadvantages, however, involved in screen-printing ofglass boards: difficulties to meet unique customer's requirements (e.g.color, size, shape, small production series etc.) in acceptable prices;long set-up time in shifting from printing one series to the printing ofanother (because the screen-frame carrying the image should bedischarged from the machine and replaced by another); color printing isinvolved with replacement of the printing frame for each color, or withthe use of a series of printers unit, each for a different color, withappropriate ink drying/curing stages in between. These and otherdisadvantages are followed by expensive human labor, equipment andproduction costs, materials and storage costs (prepared screen-printingframes should be stored after use for a future use of the sameapplication, otherwise should be reproduced for every work order), whichplaces the glass printing market at a low level comparing to printingmarkets of other raw materials.

It is an object of the present invention to disclose alternativeprinting method and printing apparatus that will allow for replacing thetraditional screen-printing machinery used in the flat glass printingindustry, while solving the above-mentioned disadvantages accompanied toscreen-printing, and in the same time opening new markets for flat glassprinting.

The method and apparatus according to the present invention areinter-alia aimed for the following purposes that are served today byscreen-printing:

Automotive—vehicle's windscreens and windows have a narrow paintedpattern (a frame) around their upper part, which protects the glue thatattaches the window to the car frame from the sun UV radiation anddecorates the windscreen;

Architecture—decorative windows for internal and external use.

Home Appliances—windows for microwave ovens, ovens, refrigerators (theinvention is not limited to oversized or wide format printing).

In order to achieve the requirements of such printed patterns, which arefar different from those of conventional printing (for example, for anautomotive windscreens: very high temperature durability, above 550° C.,resistance to soaking in warm sulfuric acid and sodium hydroxidesolutions etc.), the printed apparatus that should be developed shouldbe capable of functioning with inks that become an integral part of theglass, in an industrial process, which includes heating over 550° C.after the printing, and should have comfortable flexibility in printingeither large or small printing series, in replacing the printed imagefrom series to series and in changing colors and in full color printing.

The present invented method and apparatus deal and try to comply withsaid aims as will become more apparent from the following description.

SUMMARY OF THE INVENTION

The present invention discloses an industrial large format printingapparatus for printing glass based ink on safety flat glass, such as forthe automotive OEM (Original Equipment Manufacturer), ARG (AutomotiveReplacement Glass), Architecture and Appliances markets.

The printing apparatus of the present invention is comprised of thefollowing three basic modules: feeding and positioning module; printingmodule; and outlet module.

According to a basic semi-automated embodiment of the printing apparatusof the present invention, the feeding and positioning module and theoutlet module are one. Actually, they are formed as table, tray, orother horizontal support upon which a user can manually position a glassboard (hereinafter will be referred to also as “glass plate”) and adjustit for printing, then remove it after printing has completed, andmanually feed another glass board in a similar manner.

According to this semi-automated embodiment, the printing automationconcerns only the printing itself (i.e. the computerized operation ofthe printing head and other utility components that may be accompanyingit) while the feeding and removal of glass boards are made manually.

According to other and more mechanized semi-automated embodiments of theprinting apparatus of the present invention, the feeding and positioningmodule and/or the outlet module may comprise shifting units which canconvey the glass board from an initial upload position to a printingposition, or from a printing position to a download position, or acombination thereof (e.g. wherein both system are included in theapparatus either separately, or as walking beams serving for bothuploading and downloading applications). According to these embodimentsthe glass boards are uploaded and downloaded manually, and theautomation is in shifting them to and from the printing position.

Printing apparatuses of various intermediate degrees of automation canbe designed as a response to the market requirements, between the basicsemi-automated embodiment and between an in-line multi color fullyautomated printing apparatus, without departing from the scope of thepresent invention as will be hereinafter described, and further definedby the claims.

As mentioned above, the three modules can be designed either (a) for acompletely manual operations of uploading and downloading of glassboards (wherein the feeding and positioning module and the outlet moduleore one); (b) for a semi-automated sequential printing which allows forfeeding a next glass for printing, while the outputting of a justprinted one is made simultaneously without a halt by means of amechanized shifting unit which conveys the just printed board to anoutlet position; (c) for in-line fully automated sequential printing; orfor any intermediate degree of automation according to marketrequirements or to the preferences of specific customers.

According to the various embodiments and regardless of their degree ofautomation is preferably provided with a primary ink fixation assembly(hereinafter will be referred to also as “primary fixation assembly),which allows for safely handling an outputted glass board from theprinter to firing at a high temperature furnace, without risking theintegrity of the just printed image. According to the present inventionthe primary ink fixation assembly is preferably a part of the printingmodule thus performs the primary fixation simultaneously with theprinting such that ink droplets which have just injected from theprinting head are immediately being subject to the influence of theprimary fixation assembly.

It should be noted that after the primary fixation the glass boards aretransmitted to firing at such high temperatures such as 550° C. andabove, for a final fixation of the unique ink, which inter-aliacomprises micro particles of glass. Such new and innovative ink forinkjet digital glass printing which is a subject to a patent applicationby itself, requires however special ink system that will have theabilities to comply with its unique heterogenic suspension format.Accordingly, the printing module according to the present invention willbe further comprising at least a part of the following systems andcomponents, each of which will be further described to its particularsin the detailed description chapter: accurate printing head temperatureheating system; ink suspension maintenance system; a special electroniccontrol system for controlling the printing head; a special printinghead flushing and/or wiping system; collect trays for demo printing(known in the art as “solid bar printing”) or for margin printing.

The digital glass printer according to the present invention furtherprovides for additional important features and applications that cannotbe processed through screen-printers. One such application isduplicating the printing area by dividing the printed image to two ormore parts, each of which can utilize the full printing area of theprinter, while advancing the glass boards in the printer several timesduring the printing, correspondingly to their specific portion to beprinted. To that end, the digital glass printer according to the presentinvention is preferably comprises an accurate linear feeding system(e.g. servo controlled feeding arms—having suction cups for gripping theglass board as will become more apparent from the detailed descriptionof the invention). Furthermore in order to effectively comply with suchoversized printing procedure, the printing software of the digital glassprinter comprises an appropriate algorithm for dividing the printedimage to its parts. Such duplication of printing area cannot bepractically processed in screen-printers from several reasons, e.g. acontact between the printing screen and the glass is essentiallyrequired in screen-printing, thus printing a second image portion willdamage the formerly printed part by smearing, furthermore an accuratepositioning of a second part printing is very difficult since thefirstly printing screen should be replaced with one adapted to the imageof the second part printing wherein the accuracy of positioning of thenew screen with respect to the firstly printed image cannot bedetermined without contacting the screen to the glass surface. Thereplacement of the printing screen between following image portion iscumbersome procedure by itself.

Another feature of the digital glass printer that cannot be processed bythe traditional screen-printers is capturing the positioning of the fedglass board and digitally adapting the image position to the glass boardposition. For this purpose the digital printer according to the presentinvention is provided according to various of its preferred embodimentswith at least one CCD camera for glass board position capturing, andwith corresponding picture processing algorithm in the printing softwarecapable of glass board position recognition for determining the exactpositioning of the fed glass board, wherein another algorithm is usingfor adapting the printed image to the glass board orientation asdetermined by the position recognition algorithm. According to otherembodiments of the present invention, the glass positioningdetermination is made by sensor means other than CCD camera, e.g. bylaser distance gauge with a corresponding software algorithm. Suchelectronically processed image adjustment on the glass board to beprinted cannot be implemented in the traditional screen-printerscurrently used for glass board printing wherein the only possible imagepositioning involves physical adjustment of the screen-screen framerespective to the glass board.

Various embodiments of a printing apparatus for printing on glass boardsaccording to the present invention will be described more particularlyin following chapter of this specification.

DETAILED DESCRIPTION OF THE INVENTION

A basic embodiment of the glass printing apparatus for printing flatglass boards with glass based ink (i.e. having glass particles in theink suspension) according to the present invention, comprises; (a)horizontal support for a glass board to be printed (the horizontalsupport is preferably comprise adjustable roller, or stopper allowingfor accurate positioning of the glass board for printing, and mayfurther comprise adjustable pointed protrusions useful for positioningglass boards of non-linear shapes, and clipping or griping means forsecuring the glass board during printing); (b) at least one digitalink-jet printing head moveable from above the area of a glass boardsupported by the horizontal support by means of a respective movingmechanism, the printing head is capable of moving above the glass boardand injecting glass based ink according to positioning and injectingcommands received from a computer or controller; (c) ink supply systemin liquid communication with the at least one printing head.

The printing head moving mechanism according to the present invention iscomprised of a laterally oriented bridge carrying the printing head, theprinting head is moveable along the bridge laterally to the glass boardto form X-axis movement, and the laterally oriented bridge is movableperpendicularly to its lateral orientation along two parallel tracks orbeams to form Y-axis movement of the printing head. According to variouspreferred embodiments the movement of the printing head along the bridgeis by means of linear motor, and the movement of the bridge along thebeams is by means of ball-screw mechanism (hereinafter will be referredto also as ‘screw drive mechanism’), wherein a rod having helical threadextends along a longitudinal inner space of each of the beams andwherein a simultaneous synchronous rotation of the rods at the two beamsdrive two corresponding nuts (will be referred to hereinafter also as‘riders’) having inner threading (and preferably having bearings forfriction reduction) complementary to and matching the helical threadingof the rods. The two opposite sides of the bridge are joinedrespectively to the riders, and thus the synchronous rotation of therods shifts the bridge along the beams.

Preferably, the printing apparatus of the present invention, to itsvarious embodiments, includes a primary ink fixation system. The primaryink fixation system is comprised of at least one longitudinal heaterlocated parallel to the bridge. According to one preferred embodimentthe at least one heater is connected in parallel to the bridge in such aposition such that it advances along the glass board before the printinghead, and thus it heats lateral strip-like portions of the glass boardprior to being printed, resulting in fast drying of the ink dropletswhich contact the so heated glass surface. According to anotherembodiment the at least one heater is located in parallel to the bridgein such a position such that it advances along the glass board after theprinting head, and thus it heats lateral strip-like portions of theglass board after being printed, resulting in fast drying of the inkdroplets which are heated by the heater from above. According to anotherembodiment at least two heaters are located parallel to the bridge insuch a position such that at least one of the heaters advances along theglass board before the printing head, and thus it heats lateralstrip-like portions of the glass board prior to being printed, resultingin fast drying of the ink droplets which contact the so heated glasssurface, while the other heater is located in parallel to the bridge insuch a position such that it advances along the glass board after theprinting head, and thus it heats lateral strip-like portions of theglass board after being printed, resulting in fast drying of the inkdroplets from both upper and lower directions.

According to further embodiments of the present invention the primaryink fixation system is comprised of at least one longitudinal heaterlocated parallel to the bridge and from at least one spot heater unitlocated near the at least one printing head and moveable together withthe printing head along the bridge. According to one variation bothlongitudinal and spot heater units are designed as to heat the glasssurface close prior to the printing. According to another variation bothare designed to heat the glass surface closely after printing. Accordingto yet another variation at least one heater unit is located as to heatthe glass surface prior to printing while at least one other heater isdesigned to print the glass surface after printing.

According to further embodiments the printing direction could beswitched. Accordingly, the same heater which heats the glass surfaceprior to the printing in a first printing direction may become heatingthe glass surface after the printing in case the printing direction hasswitched.

According to various preferred embodiments the printing apparatus of thepresent invention comprises in addition to the longitudinal heatersventilation means, for dispersal of the vapors and gasses released fromthe ink after printing and during the primary fixation process. Suchvapors and gasses increase the wetness of the air near the printing, andthus delay the ink drying. In addition they may block certain amounts ofthe IR radiation emitted from the heaters from reaching at the glasssurface. Accordingly, they should preferably be dispersed. Theventilation means for dispersing the vapors and gasses fog may comprisea fan or a line of fans suspended from below the bridge, or may comprisea plurality of air blowing channels directed towards the printing areaand fed by an air flow supplied by a common air blower.

It is possible according to the present invention to print with UVcurable ink as well. Accordingly, in various embodiments of the printingapparatus of the present invention the primary ink fixation systemcomprises at least one ultraviolet lamp for UV ink curing. The at leastone UV lamp is arranged so as it moves in full correlation with themovement of the printing head, for immediate irradiation of theprinting. In case the printing head is designed to printbi-directionally along the X-axis of printing, two UV lamps areprovided, each on an opposite side of the printing head, to allow UVirradiation on the printing regardless of the printing direction (thetwo lamps can be activated alternately, however, according to the actualprinting direction).

Preferably, the printing apparatus of the present invention, to itsvarious embodiments, includes in its ink supply system means formaintaining an ink having solid micro particles to reach the at leastone printing head in a substantially unified heterogenic suspension,i.e. a suspension having a substantial uniformity in the dispersal ofits different phase ingredients, including liquids and solid nanoparticles, in any region of its volume.

Preferably, the printing apparatus of the present invention, to itsvarious embodiments comprises also printing head temperature controllingsystem, for maintaining the printing head in a temperature adapted tomanufacturer specifications of the ink to be used. Such temperaturecontrolling system is typically comprised of a heating element forheating the printing head, and of a thermostat, or of a heat sensorcommunicating with a computerized controlling means adapted to calculatethe heating element activation time or electrical current, according toa feedback from the heat sensor and according to the amount of ink to beconsumed by the printing head in real time (which could be calculatedaccording to data relating to the currently printed image).

Preferably, the printing apparatus of the present invention, to itsvarious embodiments, is further comprising printing head wiping orflushing system. The flushing system is typically comprised from asolvent reservoir in liquid communication with the at least one printinghead, and from a pump, a pressurized air system, or other effectivemeans for delivering the solvent. In case of a long term postponement ofthe printing (e.g. during non working night hours) or in other casesrequiring flushing of the printing head (e.g. ink type or colorreplacement), the solvent is directed into the printing head forflushing, preferably through appropriate filter to remove unwantedsediments. If the printing head is comprised of an array of a pluralityof basic printing heads, the flushing reservoir may communicate with allthrough appropriate manifold.

The wiping system is comprised of a wiper (typically a rubber strip heldin a gripper), wiper supporter upon which the wiper is positioned toface the bottom of a printing head to be wiped), means for bringing thewiper to a contact with the printing head bottom and for moving itlaterally for wiping off and removing ink or solvent remaining.According to one variation the wiper is held constantly near the end ofthe bridge, and the printing head is moved over the wiper through anappropriate controller command activated at the and of flushingprocedure or initiated by the printer operator. According to anothervariation the wiper supporter has means for movement along the bridge,and if so required (e.g. according to a specific form of the printinghead bottom) has also means for up and down movement, which allow fordriving the wiper supporter below the printing head, moving it up to acontact with the printing head bottom (if required), then shifting thewiper (or the printing head) laterally for wiping and removing ink orsolvent remaining.

Additional systems and assemblies may be incorporated into the variousembodiments of a glass printing apparatus of the present invention, toimprove its performances, to improve its automation facilities, or tofacilitate user control and activation procedures.

Accordingly, the printing apparatus of the present invention may furthercomprise at least one demo pre-printing or margin printing collect tray.A demo printing could sometimes be necessary (e.g. after a postponementof the printing for a time period that may cause partial drying of inkat the ink-jet apertures, or e.g. for initial acceleration of theprinting head until it reaches a substantially constant velocity andnormal ink flow) in order to obtain perfect homogeneous printing. Marginprinting is often required when a glass board should be printed adjacentto its margins. In order to allow for such demo printing or marginprinting instantly, collect trays may be provided at the sides of theprinting position, and the demo printing or the margin printing could beperformed on these trays.

To improve automation, the apparatus may further comprise glass boardoutlet convey module for removing printed glass boards from thehorizontal support to an outlet position, and/or glass board feedingconvey module for conveying glass boards from an inlet position to thehorizontal support. The feeding convey module and the outlet conveymodule may be synchronized such that when a first glass board is removedby the outlet convey module after printing, a next glass board isbrought simultaneously by the feeding convey module to a printingposition on the horizontal support.

According to various embodiments of the printing apparatus, it isfurther comprising a mechanism for elevating and lowering the printinghead respective to the glass board to be printed or for elevating andlowering the glass board to be printed, respective to the printing head(this mechanism may be a part of the glass board feeding module and/orof the glass board outlet module, both of which can have glass gripingarms having a convey movement in the glass board flow direction (e.g. bymeans of servo mechanism), and further having up and down movement (e.g.by means of pneumatic piston mechanism).

For the purpose of more detailed description of the invention, and in nomanner to limit its scope to any specific embodiment, one embodiment wasselected to be hereinafter described in details. According to thisembodiment the glass printing apparatus is comprising (a) glass boardfeeder unit for feeding and supporting glass boards underneath a digitalink-jet printing head; (b) at least one digital ink-jet printing head incommunication with a computerized controlling arrangement and capable ofinjecting glass based ink and of moving respective to a glass board tobe printed; (c) ink supply system in liquid communication with the atleast one printing head; (d) glass board outlet system for removingprinted glass boards from underneath the printing head and supportingthem until removed from the printer; (e) at least one of the followingcomponents (e1) means for maintaining an ink having solid nano particlesto reach the at least one printing head in a substantially unifiedheterogenic suspension; (e2) primary ink fixation system; (e3) glassboard location capturing system; (e4) at least one collect tray forreceiving ink during demo or margin printing; (e5) printing headtemperature controlling system; (e6) printing head wiping or flushingsystem.

The apparatus may further comprise automation control system forcontrolling and synchronizing the operation of the apparatus for asemi-automated or for fully automated sequential printing of glassboards.

According to other variations the fully automated apparatus may beincorporated into a production line as an in-line device. For thispurpose it is provided with automation control system for controllingand synchronizing the operation of the apparatus as an in-line fullyautomated printer in a production line, through communication with acentral controlling system of such production line.

According to various preferred embodiments of the printing apparatus,the glass board horizontal support is comprising a table made ofhorizontally oriented spaced bars each having a top surface withupwardly oriented tips, altogether forming an array of upwardly orientedtips upon which a flat glass board can be positioned and supported. Thetips could be made from any rigid and smooth material, e.g. metal,coated metal, plastic, Teflon or other material or combination ofmaterials having similar properties.

According to a first variation of the printing apparatus, the glassboard location capturing system comprises at least one CCD camera and acomputer algorithm for image interpretation of glass board imagesobtained by the at least one CCD camera and for determining glass boardlocation accordingly.

According to another variation of the printing apparatus the glass boardlocation capturing system is comprising at least one laser distancegauge and computer algorithm for interpreting and determining of glassboard location according to data provided by the laser distance gauge.

The present invention further relates to a method for printing flatglass boards with glass based ink, comprising; (a) providing a computermemory with image to be printed; (b) positioning a glass plate to beprinted underneath at least one digital ink-jet printing head capable ofreceiving from the computer and accordingly executing ink jettingcommands and positioning commands; (c) providing the at least oneprinting head with jetting and positioning commands corresponding to theimage to be printed; (d) supplying to the printing head glass based inkin a substantially unified heterogenic suspension in quantitiessufficient for printing the image; (e) drying or curing the image untila primary fixation is achieved sufficient for safely conveying theprinted glass plate to completing the ink fixation in a furnace.

Said method may further comprise steps for step printing of oversizedglass boards, the steps includes (f) activating computer algorithm fordividing the image to be printed to printable sub sections; (g)positioning the glass board in an initial printing position and printinga first printable sub section on the glass board; (h) shifting the glassboard to a second printing position and printing a printable sub sectioncorresponding to the second printing position; (i) repeating step ‘h’until all the sub sections are printed.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 illustrates in an isometric view a selected embodiment of thedigital ink-jet printer of the present invention.

FIG. 2 illustrates a side view of the heaters of the primary inkfixation system according to a selected embodiment of the printer of thepresent invention.

FIG. 3 illustrates a selected embodiment of the ink supply system andthe flushing system of a digital ink-jet glass printer according to thepresent invention.

FIG. 4 illustrates an isometric view of a selected embodiment of anactual mid ink tank of an ink supply system according to a selectedembodiment.

FIG. 5 illustrates an isometric view of a printing head wiping assemblyaccording to a selected embodiment.

FIG. 6 illustrates a side view with partial cross sectional view of aprinting head capping assembly according to a selected embodiment of thepresent invention.

FIG. 7 illustrates a top view of glass board in printing position, andindicates the location where a margin printing should be performed.

FIG. 7 a illustrates a portion of what illustrated by FIG. 7, in anenlarged transversal cross sectional view.

FIG. 8 illustrate top view of two step printing of oversized glassboard, and pre-printing of test marks, according to the presentinvention.

DETAILED DESCRIPTION OF THE FIGURES

FIG. 1 illustrates in an isometric view a selected embodiment of thedigital ink-jet printer (1) of the present invention. The illustratedprinter comprises a horizontal support (2) made of a plurality of spacedbars (3), upon which can be positioned a glass board (not illustrated)underneath a digital ink-jet printing head unit (4). This specificprinting head unit is internally constructed from an array of eightbasic printing heads arranged in two rows of four. For example, SpectraNova 256 printing head could be used as a basic printing head. ThisModel of printing head comprises four electrically independentpiezoelectric sections, each of the four having a jet command line and64 channels (ink-jet orifices), each channel has a separate digitaladdress for obtaining from a computer (having the image data) a “0” or a“1” as a jetting instruction for the currently printed dot. The eightbasic printing heads of the array are loaded with the specific jettinginstruction of each orifice according to the data of a specific imageregion to be currently printed by the 8×4×64 orifices, as supplied bythe system computer (5) (or by alternative external computer).Thereafter, upon receipt of a jet command through the jet command line,each of the orifices instructed to print a dot injects an ink droplet.The speed of the droplet could be tuned by controlling the voltageamplitude of the pulse supplied to the jet command line, and the dropletvolume can be tuned by controlling the pulse width.

The printing head unit (4) is moveable along a bridge (6) laterally tothe glass board feeding direction A1 to form X-axis movement. The bridgeis formed from hollow bar of a rectangular cross section view, Thelaterally oriented bridge is movable perpendicularly to its lateralorientation along two parallel tracks or beams to form Y-axis movementof the printing head. the movement of the printing head unit (4) alongthe bridge (6) is by means of linear motor comprised of a coil memberconnected to the backside of the printing head unit (4) and of magnetsfixed along the length of one the side walls of the bridge (6). Thelinear motor magnets and longitudinal space are covered by flexiblefolding wall parts (7 a) and (7 b) which the coil member of the linearmotor pass in between to run along the magnets. When the printing headmoves to the left the wall part (7 b) is shrinking by the coil memberwhich protrudes from the printing head backside, while the wall part (7a) is expanding. The opposite happens when the printing head moves tothe right. The printing head (4) communicates with the other printerparts (i.e. ink supply, solvent supply, electric and electronic systems)through cable strip (8) which is foldably extended through the loop (8a) between the print head interface housing (4 a) on its one end and theprinter system cabin (9) on its next end. The ink tank (10) and thesolvent tank are connected to the bridge (6) according to the presentembodiment, however, according to other embodiments are located insidethe printer system cabin (9) or the printer system cabin (9 a) on theother side of the printer. In addition to its X-axis (along the bridge)and Y-axis (by the bridge) motions, the printing head unit is moveablealso in the Z-axis by means of servo motor located inside thecylindrical housing (4 b). Thus the printing head unit could be adjustedto an optimal printing height from above the glass surface to beprinted. The height of the printing head unit (4) above the glasssurface could be adjusted automatically by means of a laser distantgauge which provides the printer computer (5) with height data, whereinin return the computer adjusts the printing head unit (4) height to anoptimal predetermined height which has be recognized in advance asresulting with optimal printing. Accordingly, the height of the printinghead unit from above the glass surface may be kept unchanged, regardlessof the thickness of the glass board to be printed. According to otherembodiments of the present invention the printing head may provided alsowith controllable pivot movement about its vertical axis, useful fortracing and printing in curved lines.

The laterally oriented bridge (6) is movable perpendicularly to itslateral orientation along two parallel beams (12) and (12 a) to formY-axis movement of the printing head unit (4). According to the presentembodiment the movement of the bridge (6) along the beams (12) and (12a) is by means of screw drive mechanism, wherein a rod having helicalthread extends along a longitudinal inner space of each of the beams(12) and (12 a) and wherein a simultaneous synchronous rotation of therods at the two beams (12) and (12 a) drives two riders (nuts) havinginner helical threading (and preferably having bearings for frictionreduction) complementary to and matching the helical threading of therods. The two opposite side posts (14) and (14 a) of the bridge (6) arejoined respectively to the riders inside the inner space of the beams(12) and (12 a), and thus the synchronous rotation of the rods shiftsthe bridge (6) along the beams. In order to protect the screw drivesystems and the bridge from unwanted strain and pressure forces that mayoccur in case of differentiation in the rotation starting moment betweenthe two helical threading rods (which in turn may result in diagonaldeviation of the bridge from its normal lateral orientation), the bridgemay be joined to the nut riders of the ball screw through a pivotablpost on its one end, and through a pivotable sliding track on its otherend, such that in case of diagonal deviation of the bridge from itsneutral lateral orientation, the bridge can pivot on its one end on thepivotable post, and slide and pivot on its other end on the pivotablesliding track, for compensating against its asynchronous advancing alongthe two screw drives. Accordingly, the bridge post (14 a) of the presentembodiment is pivotable, and the bridge is connected to its other post(14) through a pivotable sliding track (14 b)

The beams are covered from their five directions by metal panels, whilethe sixth (upper) direction is covered by accordion-like folding cover(13) and (13 a), respectively, which allow for movement of the bridgeside posts (14) and (14 a) along the beams (12) and (12 a) while theaccordion-like folding covers (13) and (13 a) shrink or expand accordingto the position of the posts (14) and (14 a) respective to the beams. Aprinting sequence in the illustrated printed starts by placing a glassboard on the feeding table (15), which similarly to the horizontalsupport (2) is also made of a plurality of spaced bars (16). Each bar(16) has on its top several spherical bearings spaced from one anotherand protruding upwardly, such that when a glass board is placed on thefeeding table (15) it can easily be shifted carried on the bearings, toan appropriate alignment position. Rulers or stoppers may be applied ata predetermined positions on the bars, either parallel or transverselyto the longitudinal directions of the bars, as marginal limits to aglass board to be printed. After the glass board is placed, the printeroperator instructs the printer through the printer computer terminal (5a) or by pressing a pedal (not illustrated), to grip the board firmly onthe feeding table, which is preformed by means of upwardly orientedsuction cups which are then vacuumed to firmly grip the glass board frombelow, and stress it against the bars to prevent undesired movement. Atleast two walking beams (17) are placed between the table spaced bars(16). The walking beams has also upwardly oriented suction cups forcapturing and gripping a glass board. Upon printer operator instruction(either through the computer terminal, or by secondly pressing thepedal) the walking beams are lifted slightly by means of pneumaticpistons to contact the lower surface of the glass board with theirsuction cup, then grip it firmly when the suction cups are vacuumed.After capturing of the glass board by the walking beams, the vacuum inthe suction cups of the feeding table is released, and thereafter thewalking beams are further lifted by the pneumatic pistons to elevate theglass print slightly above the spaced bars level, then a servo systempulls the walking beams laterally between the spaced bars of the feedingtable and of the horizontal surface, with the glass board gripped fromabove by their suction cups, until the glass board is brought exactlyabove its printing position, and the lateral movement of the walkingbeams is stopped. The glass board is now lowered by the pneumaticpistons slightly lowering the walking beams, such that the lower surfaceof the glass board contacts an array of upwardly oriented tipsprotruding from the upper end of the spaced bars (3) of the horizontalsurface (2). The tips could be produced from any smooth rigid material,such as metal, coated metal, plastic or Teflon, or the like. After theglass board is captured and gripped by upwardly oriented suction cupslocated between the spaced bars (3) of the horizontal surface, thevacuum is released from the suction cups of the walking beams (15) whichcould then are further lowered slightly by the pneumatic pistons. A nextglass board can now be placed on the feeding table in a similar manneras the first one, while the first one is being printed with theappropriate image as instructed by the system computer (5) or by anyexternal computer in communication with the printing head unit (4).After completing the printing, the walking beams which meanwhile havebeen returned by the servo to face the bottom surface of the next glassboards, are elevated by the pneumatic piston for capturing the nextglass board similarly to the capturing of the first, now printed, glassboard, with the difference that now the walking beams capturesimultaneously the first, now printed, glass board, at its printingposition on the horizontal support. After both glass boards beencaptured by the walking beams suction cups, the suction cups of thefeeding table and of the horizontal support are released, and then bothglass plates are slightly elevated above the spaced bars (16) and (3),respectively, by the pneumatic pistons which elevate the walking beams,and while the servo controlled lateral movement of the walking beamsbrings the next glass board exactly above its printing position, thefirst, now printed, glass board reaches an outlet position above anoutlet table (not illustrated) which can be designed similarly to thefeeding table (15), or can be a conveyor belt or any other support whichcan receive printed glass board and hold them until removal. A thirdglass board can be meanwhile loaded to the feeding table (15), while thesecond glass board is lowered to contact the horizontal support andwhile simultaneously the first glass board is lowered to contact theoutlet table or conveyor. Thus, in a sequential printing process, threeglass boards are treated simultaneously on the illustrated printerembodiment, one of which—in a printing position, one in the feedingtable, and one in the outlet module.

FIG. 2 illustrates a side view of the heaters (18)(19) and (20) of theprimary ink fixation system according to a selected embodiment of theprinter of the present invention. The primary ink fixation system allowsfor drying the ink liquid vehicle, which terminates its duty immediatelyafter the injected ink droplets reach their destination on the glassboard. The evaporation of the ink liquid vehicle for a primary fixationof the printed image on the glass surface is essential for furtherhandling the glass board along a production line without risking theimage integrity e.g. as a result of smearing wet ink by unintentionaltouch, or as a result of wet ink leaking while changing the orientationof a printed glass board from horizontal to a vertical orientation.Contrarily to digital ink-jet printing on other materials, in securityglass printing this drying procedure does not become final because theglass board should still be fired in at least 550° C. furnace for finalfixation of the image by melting the glass nano-particles of the glassbased ink using for such printing. Therefore, the drying processaccording to the present invention is referred to as “primary fixation”.A basic primary ink fixation system is comprised of at least onelongitudinal heater (18) or (19) located parallel to the bridge (6).According to one basic embodiment the at least one heater is the rearheater (19) which is connected parallel to the bridge (6) in such aposition such that it advances along the glass board before the printinghead (4), and thus it heats lateral strip-like portions of the glassboard prior to being printed, resulting in fast drying of the inkdroplets which contact the so heated glass surface. According to anotherbasic embodiment the at least one heater is the front heater (18) thatis located parallel to the bridge (6) in such a position such that itadvances along the glass board after the printing head (4), and thus itheats lateral strip-like portions of the glass board after beingprinted, resulting in fast drying of the ink droplets resting already onthe glass surface which are thus being heated by the front heater (18)from above. According to a third basic embodiment at least the twoheaters (18) and (19) are located parallel to the bridge (6) in such aposition such that at least one of the heaters advances along the glassboard before the printing head, and thus it heats lateral strip-likeportions of the glass board prior to being printed, resulting in fastdrying of the ink droplets which contact the so heated glass surface,while the other heater is located in parallel to the bridge in such aposition such that it advances along the glass board after the printinghead, and thus it heats lateral strip-like portions of the glass boardafter being printed, resulting in fast drying of the ink droplets fromboth upper and lower directions. According to this third embodiment theprinting direction along the Y-axis could be inverted with nosignificant affect on the drying process which according to thisembodiment comprises both pre-print heating and post-print heating,regardless of the printing direction.

According to further embodiments of the present invention the primaryink fixation system is comprised of at least one longitudinal heater(18) or (19) located parallel to the bridge (6), and from at least onespot heater unit (20) located near the at least one printing head unit(4) and moveable together with the printing head unit (4) along thebridge. According to one variation both longitudinal (18) or (19) andspot heater (20) units are designed as to heat the glass surface closeprior to the printing. According to another variation both (18) or (19)and (20) are designed to heat the glass surface closely after printing.According to yet another variation at least one heater unit (18) or (19)or (20) is located as to heat the glass surface prior to printing whileat least one other heater (18) (or (19) or (20) is designed to print theglass surface after printing. According to further embodiments theprinting direction could be switched. Accordingly, the same heater whichheats the glass surface prior to the printing in a first printingdirection may become heating the glass surface after the printing incase the printing direction has switched.

It is possible according to the present invention to print with UVcurable ink as well. Accordingly, in various embodiments of the printingapparatus of the present invention the primary ink fixation systemcomprises at least one ultraviolet lamp (21) for UV ink curing.

The heater units (18) and (19) may be connected directly to the bridge(6), or through side posts directly to the screw drive inside the sidebeams. The heater unit (20) and the UV lamp (21) may be connecteddirectly to the printing head unit (4) or to an arm such as the onethrough which the printing head unit is connected to the linear motorinside the bridge space.

FIG. 3 illustrates a selected embodiment of the ink supply system andthe flushing system of a digital ink-jet glass printer according to thepresent invention. According to the present embodiment the ink supplysystem is comprised of a main ink tank (30) having a stirrer (31) drivenby electrical motor (32) fixed to the cap unit (33) of the main inktank. Ink could be added to the main ink tank through lid (34) locatedon the cap unit (33). The ink in the main ink tank is circulated througha circulation line comprising the inlet and outlet circulation pipes (35a) and (35 b) that are connected to the main tank circulation pump (35).The ink supply system is further comprising a mid ink tank (36) whichreceives its ink content (37) from the main ink tank (30). According tothe illustrated embodiment the main ink tank (30) is supplying its inkto the mid ink tank (36) through a junction (35 c) in the circulationpipe (35 b), and further through pipe (38), 5 micron fiber-made inkfilter (39), pipe (40), 14 micron steel made secondary filter (41), andpipe (42). The 14 micron filter (41) is located past the 5 micron filter(39) in order to block fibers that may be tear and released from the 5micron fiber-made filter (39) during time. The 5 micron filter (39) isaimed to filter the ink from particles that may damage the effectiveoperation of the printing head. The ink content (37) of the mid ink tank(36) is also circulated, through the circulation line comprising theinlet and outlet pipe segments (43 a) and (43 b) and the mid ink tankcirculation pump (43). The ink tank (36) is further comprising a float(44) which is aimed to maintain the ink content (37) in a substantiallyfixed level, by means of a valve (not illustrated) which opens there-circulation pipeline (45) to the flow of ink from the mid ink tank(36) back to the main ink tank (30). The ink flow from the main ink tankto the mid ink tank (36) and back to the main ink tank (30) is generatedby the main ink tank circulation pump (35) which is capable of forcingthe ink flow through both the main ink tank circulation line (i.e.through pipes (35 a) and (35 b)) and the ink supply path comprising thepipes (38), (40), (42), and the filters (39)(41), and back to main inktank (30) via the recirculation pipeline (45). The mid ink tank (36) isthus capable of supplying unified heterogenic ink solution to theprinting head unit. This is done through ink supply pipe (46) which isin liquid communication with the array of the eight printing heads (47)through eight channel manifold switching valve unit (48) and througheight printing head input pipes (49) (only one of the eight pipes (49)is illustrated in this figure, the other seven are connectedrespectively to the other seven printing heads of the array). Theprinting head unit returns surplus ink volumes back to the main ink tankthrough eight pipes (50) (only one of the eight pipes (50) isillustrated in this figure, the other seven are connected respectivelyto the other seven printing heads of the array) and through the inkfilter (52) and the pipe (51), thus forming another ink circulationpath.

The printing head flushing system is comprised of the solvent tank (53),solvent pump (54), solvent by-pass inlet and outlet pipes (54 a) and (54b), solvent supply line (55 a) (55 b) and 5 micron filter (56). Whenneed rise to flush the printing heads, the flush pump (54) is activatedand the valve of the eight channel manifold switching valve (48) isswitched to block the ink flow from the ink supply line (46) and to letthe solvent flowing from the solvent supply line (55 b) to the printingheads, which are thus being flushed by a solvent being injected throughthe plurality of injection orifices of the printing head unit. In casethe switching valve (48) blocks the solvent supply line (55 b) and thepump (54) still forms pressure, it is released through the by pass lineformed by pipes (54 a) and (54 b).

FIG. 4 illustrates an isometric view of a selected embodiment of anactual unit comprising mid ink tank, eight channel manifold andswitching valves, of an ink supply system according to a selectedembodiment. The mid ink tank according to the illustrated embodiment iscomprised of an ink, container (60) having circulation line inlet (61)and circulation line outlet (63), and an eight outlets hub comprisingthe outlets (62 a) to (62 h). The eight outlets (62 a) to (62 h) are tobe connected respectively to ink inlets (64 a) to (64 h) (only two ofwhich—(64 a) and (64 e) are visible in the illustrated perspective view)of eight switching valves (65 a) to (65 h) each of which is controllablethrough a pair of electrical wires (65) and (67) to select between astate wherein the valve outlets (68 a) are (68 h) is in liquidcommunication with the respective ink inlets (64 a) to (64 h) andbetween a state wherein the valve outlets (68 a) to (68 h) are in liquidcommunication with the respective solvent inlet (69 a) which cooperateswith the valves (65 e) to (65 h), or (69 b) which cooperates with thevalves (65 a) to (65 d). the valves outlets (68 a) to (68 h) areconnected respectively to eight printing head of a printing head arrayunit (not illustrated). The ink container (60) receives its ink throughcentral ink inlet (70), and it further has a float inside (hidden inthis figure) which controls the ink flow through the container (60) tomaintain a substantially fixed ink level inside.

FIG. 5 illustrates an isometric view of a printing head wiping assemblyaccording to a selected embodiment. The wiping assembly (80) isconnected near one end of the bridge (81) such that the printing head(not illustrated in this figure) could be brought to a wiping positionfrom above the wiping assembly (80). The wiping assembly comprises abath tube (82) with two upwardly oriented wipers (83 a) and (83 b). Thebath tube (82) is for receiving flushing solvent injected through theplurality of injection orifices of the printing head during a flushingprocedure. At the end of the flushing procedure, the orifices may stillhave solvent and ink remaining. These should be wiped off. The wiping isexecuted in two main motions. The first motion is performed by thevertical pneumatic piston (84) which elevates the bath tube (82) alongthe vertical sliding tracks (85 a) and (85 b) such that the wipers (83a) and (83 b) contact the bottom of the printing heads array. The secondmotion is performed by the horizontal pneumatic piston (86) which slidesthe bath tube (82) along the horizontal sliding tracks (87 a) and (87 b)such that the wipers (83 a) and (83 b) move over the printing headsinjection orifices, thus wiping the remaining solvent and ink dropletssuspended from the bottom of the printing heads array. Thereafter thevertical piston may lower the bath tube (82). The wiping assemblyfurther comprises self flushing device (88) having a plurality ofapertures (88 b) (which cannot be observed in the illustratedperspective since they face the opposite side of the self flushingdevice (88)) and (88 a), through which solvent may flow upon activation,to flush the wipers (83 a) and (83 b). before such activation, the bathtube (82) with the wipers is brought by the horizontal pneumatic piston(86) to a position underneath the self flushing device (88), thenelevated by the vertical piston (84) such that the aperture groups (88a) and (88 b) are exactly facing the wipers (83 a) and (83 b),respectively, thus flushing the wipers with jets of solvent.

FIG. 6 illustrates a side view with partial cross sectional view of aprinting head capping assembly according to a selected embodiment of thepresent invention. Four printing heads (90 a) to (90 d) are illustratedin a vertical cross sectional view. Each of the printing heads has atits bottom a plurality of ink injecting orifices (not illustrated inthis figure) which preferably should be capped whenever the printer isnot in use (i.e. during night hours) in order to prevent drying of inksediments inside the printing heads. The capping is made by a resilientand liquid opaque pad (91) which is supported by a rigid plate (92)connected through adjusting springs (93) (only one of which can beobserved in the illustrated cross section view) and through bolts (94)(only one of which can be observed in the illustrated cross sectionview) to a base plate (95) which is connected to the top end of avertically oriented piston. When capping of the printing head isrequired, the printing head is brought to a position above the cappingassembly, and the piston is elevated such that the capping pad (91) isstress against the bottom of the printing heads (90 a) to (90 d) thuscapping their injection orifices in an appropriate force as regulated bythe springs (93). The pad (91) is made of a resilient material whichallows for an enhanced contact of the pad surface with the bottomsurface of the printing heads.

FIG. 7 illustrates a top view of glass board in printing position, andindicates the location where a margin printing should be performed. Aglass board (201) to be printed is illustrated in a printing position,supported by a horizontal support made of a plurality of spaced bars(200 a) to (200 j) each of which is provided on its right side with acollect tray (202) for demo printing.

FIG. 7 a illustrates a portion of what illustrated by FIG. 7, in anenlarged transversal cross sectional view. The corner (201 a) of theglass board (201) should be printed, and therefore in order to preventink spoilage it is positioned from aboe a collect tray (202) which isattached to a respective bar (200 h) of the horizontal support uponwhich rest the glass board in printing position. When the corner (201 a)is printed, ink that may be injected beyond the edges of the glass board(201) is collected by the collect tray (202). The collect tray (202) maybe equipped with a strip (203) of spongy material or cloth for receivingthe ink. The spongy strip (203) could be easily replaced from time totime, thus the collect tray could be maintained in well condition forlong terms. The same collect tray could be utilized for demo printingwhen need rise to initialize a printing with the printing heads alreadyin normal printing conditions (i.e. after acceleration and in normalspeed and ink flow).

FIG. 8 illustrate top view of two step printing of oversized glassboard, according to the present invention. An oversized glass board(211) to be printed is illustrated in a first printing positioncorresponding to printable a sub section (212) being a first part froman oversized image to be printed. The oversized glass board is supportedon a horizontal support made of a plurality of spaced bars (210 a) to(210 j). Upon completion of printing the first printable sub section(212) which corresponds to the glass board portion now located in thefirst printing position, the oversized glass board is shifted to asecond printing position, and a corresponding printable sub-section ofthe image is printed. This illustration relates to an oversized glassboard which require 2 stage printing for having a complete image. Itcould be appreciated however that 3, 4 or other number of multi stageprinting stages could be performed in a similar manner (i.e. eachprinted sub section may be considered a first, respective to the nextone), in case glass board oversize requiring such numbers of subsections to be printed.

Another advantage of the digital ink-jet glass printer according to thepresent invention, is the ability for facile pre-printing test.Pre-printing test is especially required when printing glass boards thatare already cut to their final shape and size, and wherein the image tobe printed has portions that are adjacent the margins of the glassboards, as is the case in the present figure. Pre-printing test marks(213) and (214) could easily be printed prior to printing the margins(212). This test marks will then be covered by the actual printing. Thepre-printing test is not linked to a multi stage printing, and isrecommended whenever the material is already cut to its final shape andthus a deviation in the image positioning may not have remedy later onby cutting the material according to the image location. Accordingly,the present invention provides for using cut and shaped glass plates,and printing them accurately. It can be appreciated that inscreen-printing machine such pre-printing of test marks is not sofacile, and requires a special frame to be prepared with the test marksalone.

1. A printing apparatus for printing ink on glass boards, comprising: ahorizontal support for a glass board on which ink having solid particlesis to be printed; at least one digital ink-jet printing head; and an inksupply system comprising: a main ink tank, a stirrer positioned withinthe main ink tank, a closed circulation line for circulating the ink outof the main ink tank and back into the main ink tank using a firstcirculation pump, a mid ink tank, a first ink supply pipe connecting ajunction in the closed circulation line to the mid ink tank, and asecond ink supply pipe connecting the mid ink tank to the at least onedigital ink-jet printing head, wherein the ink supply system isconfigured to provide the ink from the main ink tank to the least onedigital ink-jet printing head through the closed circulation line, thefirst ink supply pipe, the mid ink tank and the second ink supply pipeto control dispersal of liquid and the solid particles in the main andmid ink tanks, and to maintain the ink provided to the at least onedigital ink-jet printing head in a substantially unified heterogenicsuspension.
 2. The printing apparatus according to claim 1, furthercomprising a printing head temperature controlling system.
 3. Theprinting apparatus according to claim 1, further comprising at least onecollect tray useful for demo or margin printing.
 4. The printingapparatus according to claim 1, further comprising a printing headwiping or flushing system.
 5. The printing apparatus according to claim1, further comprising a glass board outlet convey module for removingprinted glass boards from the horizontal support to an outlet position.6. The printing apparatus according to claim 1, further comprising aglass board feeding convey module for conveying the glass boards from aninlet position to the horizontal support.
 7. The printing apparatusaccording to claim 1, wherein the horizontal support comprises a tablemade of horizontally oriented spaced bars each having a top surface withupwardly oriented tips, altogether forming an array of upwardly orientedtips upon which a flat glass board can be positioned and supported. 8.The printing apparatus according to claim 1, further comprising amechanism for elevating and lowering the digital ink-jet printing headrespective to the glass board to be printed or for elevating andlowering the glass board to be printed respective to the digital ink-jetprinting head.
 9. The printing apparatus according to claim 1,comprising: a flushing system coupled to the at least one digitalink-jet printing head.
 10. The printing apparatus according to claim 1,comprising an additional closed circulation line for circulating the inkout of the mid ink tank and back into the mid ink tank using a secondcirculation pump.
 11. The printing apparatus according to claim 1,wherein the ink supply system comprises a recirculation pipeline todeliver ink from the mid ink tank back to the main ink tank.
 12. Theprinting apparatus according to claim 1, wherein the ink supply systemcomprises at least one float in the mid ink tank connected to at leastone valve such that the ink content of the mid ink tank is maintained ata substantially constant level.
 13. The printing apparatus according to1, further comprising a multichannel manifold switching valve unitconnecting the at least one digital ink-jet printing head to the inksupply system.
 14. The printing apparatus according to claim 1, whereinoutlet pipes from the at least one digital ink-jet printing head deliversurplus ink back to the ink supply system.
 15. The printing apparatusaccording to claim 1, comprising a ventilation system for dispersing inkvapors and gasses that are released from printed glass boards.
 16. Theprinting apparatus according to claim 1, comprising an automaticprinting head height system for maintaining the printing head at apredetermined height above the glass board to be printed.
 17. Theprinting apparatus according to claim 1, further comprising a primaryink fixation system.
 18. The printing apparatus according to claim 17,wherein the primary ink fixation system comprises at least onelongitudinal heater located and moveable parallel to the bridge.
 19. Theprinting apparatus according to claim 17, wherein the primary inkfixation system comprises at least one longitudinal heater located andmoveable parallel to a laterally oriented bridge carrying the at leastone digital ink-jet printing head and from at least one heater unitlocated near the at least one digital ink-jet printing head and moveabletogether with the digital ink-jet printing head along the laterallyoriented bridge.
 20. The printing apparatus according to claim 17,wherein the primary ink fixation system comprises at least oneultraviolet lamp for UV ink curing.
 21. The printing apparatus accordingto claim 1, further comprising a glass board location capturing system.22. The printing apparatus according to claim 21, wherein the glassboard location capturing system comprises at least one CCD camera and acomputer algorithm for image interpretation of glass board imagesobtained by the at least one CCD camera and for determining glass boardlocation accordingly.
 23. The printing apparatus according to claim 21,wherein the glass board location capturing system comprises at least onelaser distance gauge and computer algorithm for interpreting anddetermining of glass board location according to data provided by thelaser distance gauge.
 24. The printing apparatus according to claim 1,comprising at least one filter between the main ink tank and the mid inktank.
 25. The printing apparatus according to claim 24, wherein the atleast one filter is 5-micron-fiber-made ink filter.
 26. The printingapparatus according to claim 24, wherein the at least one filter is14-micron-fiber-made ink filter.
 27. The printing apparatus according toclaim 1, comprising: a moving mechanism having a laterally orientedbridge carrying the digital ink-jet printing head, wherein the printinghead is moveable along the bridge laterally to the glass board to forman X-axis movement, and the laterally oriented bridge is movableperpendicularly to its lateral orientation along two parallel tracks orbeams to form a Y-axis movement of the printing head.
 28. The printingapparatus according to claim 27, comprising a pivotable post forsupporting the bridge on its one end and pivotable sliding track forsupporting the bridge on its second end.
 29. The printing apparatusaccording to claim 28, further comprising an automation control andsynchronization system for providing a semi-automated or fully automatedsequential printing.
 30. The printing apparatus according to claim 28,further comprising an automation control and synchronization system forproviding an in-line fully automated printer in a production line.
 31. Amethod for printing ink on glass boards, comprising: providing a digitalimage to be printed; positioning a glass board to be printed underneathat least one digital ink-jet printing head capable of receiving andexecuting ink jetting commands and positioning commands; providing theat least one digital ink-jet printing head with jetting and positioningcommands corresponding to the digital image to be printed; supplying tothe digital ink-jet printing head a glass-based ink from an ink supplysystem having a main ink tank and a mid ink tank by continuouslycirculating the glass-based ink contained in the main ink tank in aclosed circulation line using a circulation pump and concurrentlystirring the glass-based ink contained in the main ink tank, wherein theglass-based ink is supplied to the at least one digital ink-jet printinghead through a junction in the closed circulation line to the mid inktank and from the mid ink tank to the at least one digital ink-jetprinting head while controlling dispersal of liquid and solidingredients in the main ink tank and mid ink tank and maintaining theglass-based ink in a substantially unified heterogenic suspension inquantities sufficient for printing the digital image; and drying orcuring the digital image until a primary fixation is achieved andconveying the printed glass board to complete ink fixation in a furnace.32. The method according to claim 31, further comprising: activating analgorithm for dividing the digital image to be printed to printable subsections; positioning the glass board in an initial printing positionand printing a first printable sub section on the glass board; shiftingthe glass board to a second printing position and printing a printablesub section corresponding to the second printing position; and repeatingthe step of shifting the glass board to a second printing position andprinting a printable sub section corresponding to the second printingposition until all of the sub sections are printed.
 33. The methodaccording to claim 31, further comprising pre-printing of test marksprior to actual printing of the digital image.